JPS6323415A - Pulse generator - Google Patents

Abstract

PURPOSE:To generate a pulse at always prescribed leading timing by detecting a half value of a peak voltage from an input signal having periodicity, comparing it with the input signal and using the coincident point as the leading point of the pulse. CONSTITUTION:Only a 4.5MHz beat is extracted from an output signal of a video detection circuit 38 by a band pass filter 39, subject to AM detection by an AM detection circuit 40, the one is inputted to a pulse generating circuit 41. The other is inputted to a peak detection circuit 42 and a peak voltage of an output waveform is detected, a half value of the peak voltage is outputted by a half value detection circuit 43 and the result is inputted to a pulse generating circuit 41. The pulse generating circuit 41 compares the AM detection output with a half value of the peak voltage of the AM detection output and when the voltage of the AM detection output is higher, a pulse is generated. The pulse width from the leading time is adjusted in the pulse by a pulse width adjuster 42a and the amplitude is increased by an RF amplifier 35 for a period when the pulse is inputted, the scrambled synchronizing signal is descramble.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a pulse generator, and more specifically, for generating pulses for descrambling scrambled video signals in cable television, for example. This invention relates to a pulse generator.

(Prior Art) CATV (cable television) is available for a fee, and general users can only watch videos by signing a contract with a cable television station.

In other words, the synchronization signal part of the CATV video signal is scrambled to prevent unauthorized viewers from viewing the video.
By signing a contract with the cable television station, the user can descramble the scrambled synchronization signal and watch the video.

Next, a conventional example will be explained using FIG. 7.

In addition, in this FIG. 7, only the pulse generator section that generates the pulse for descrambling the scrambled synchronization signal is shown, and the AM signal input 1 in FIG. 7 is the audio signal of the television signal. 6 That is,
In this conventional example, a signal for descrambling is applied to the audio signal by AM modulation, a descramble signal is detected from this signal, a pulse for descrambling is generated by this detected signal, and this pulse is applied to the video signal. The scrambled synchronization signal is descrambled by adding it to the sync signal, so that a correct and synchronized image can be viewed.

In FIG. 7, 1 is an AM modulation signal input, 2 is an AM detector, 3 is an AM detector output, 4 is an integrator, 5 is a reference voltage,
6 is a threshold voltage, 7 is a pulse generation circuit that performs voltage comparison and generates a rectangular pulse, 8 is a rectangular pulse output, and this pulse 8 is supplied to the video signal section to generate a scrambled signal on the disc. Do a rumble.

The AM modulated signal 1 is detected by an AM detector 2 and becomes an AM detector output 3, which is input to one of the pulse generation circuits.

Further, the AM detector output 3 is integrated by an integrator 4, and the voltage applied to the reference voltage 5 becomes a threshold voltage 6, which is input to the other side of the pulse generation circuit 7. The pulse generating circuit 7 generates a rectangular pulse when the voltage of the AM detector output 3 is higher than the threshold voltage.

The integrator 4 generates the average voltage of the AM detector output 3 and shifts the threshold voltage 6 to compensate for fluctuations in the rise timing of the rectangular pulse when the level of the AM modulation signal input 1 fluctuates due to transmission conditions, etc. work to do.

(Problems to be Solved by the Invention) In the conventional configuration described above, the output voltage of the integrator 4, that is, the DC level is
It was possible to follow the wave height value of the detector output and correct the deviation in the timing of the rise of the rectangular pulse output, but if the AM modulation degree differs due to the accuracy of the transmitter, etc., the output voltage of the integrator 4, that is, the DC level does not vary, and only the peak value of the AM detector output varies for each transmission channel, so it is not possible to correct the shift in the rise timing.

If this deviation becomes large, the video signal side receives the rectangular pulse output at the wrong timing, so descrambling is not performed accurately, and it becomes impossible to reproduce a normal, synchronized video. This will be explained based on FIG.

FIG. 8(a) shows the case of standard AM modulation degree.

The standard modulation depth is the peak voltage ratio of IA and IB, for example 6.
(dB) and the reference voltage is determined so that a rectangular pulse is generated at 50% of the AM detector output. In addition, IC has a threshold voltage, LD
is the AM detector output, and IE is the rectangular pulse.

Figure 8(b) shows the case where the modulation degree is larger than the standard. In such a case, the threshold voltage does not follow the change in the AM modulation degree, so the rectangular pulse is generated at 50% or less of the NM detector output. However, the rising timing is earlier than in the case of FIG. 8(a).

FIG. 8(C) shows the case where the degree of modulation is smaller than the reference, and since the rectangular pulse is generated at 50% or more of the AM detector output, the rising timing is delayed compared to the case of FIG. 8(a). When the situation as shown in FIGS. 8(b) and 8(c) occurs, descrambling is not performed accurately and it is not possible to view correct synchronized images.

An object of the present invention is to eliminate the conventional drawbacks and to generate a pulse at a constant rising timing even if the modulation degree of the modulation signal input varies, and to stably operate a circuit that receives this pulse. .

(Means for Solving the Problems) The pulse generator of the present invention includes a peak detection circuit that detects a constant peak voltage from a periodic input signal, a half-value detection circuit that detects the half-value of the peak voltage, and It consists of a pulse generating circuit that compares the half value with the input signal and uses the point where they match as the rising point of the pulse.

(Function) With the above configuration, pulses are always generated with 50% of the signal as the threshold, so even if the level or degree of modulation of the modulation signal changes, the pulses are always generated at a constant timing, and the circuit that receives the pulses It can perform stable operation.

(Example) An example of the present invention will be described below. In this example, in CATV, a scramble signal is applied to the synchronization signal of the video signal, and the synchronization signal is disturbed. An example in which a signal for correctly descrambling a disturbed synchronization signal is AM-modulated into an audio signal will be described.

In FIG. 2, numeral 10 is a cable television station, which is equipped with channels 11 to 82 12.

Of these, only one channel 11 converts ordinary radio wave broadcasting into a cable TV signal, in which airborne radio waves are received by an antenna 13, demodulated by a demodulator 14, and the video signal and audio signal are sent to a modulator, respectively. 15 modulates it into a cable TV signal, mixes it with signals of other channels in a mixer 10A, amplifies it in an amplifier 16, distributes it to each home in a distributor 17, and sends it to a television receiver 19 via a set-top terminal 18. Audio and video playback is now possible. This 1 channel 11 is simply a modulation of ordinary air broadcast radio waves for cable television,
It is free, and as a matter of course, the synchronization signal of the video signal is not disturbed by the scramble signal.

However, channels 2 to 82 and 12 are broadcasts unique to this cable television station 10, so they are chargeable and cannot be viewed by anyone other than a subscriber.

In other words, in these channels, radio waves from the program production station are received by the satellite broadcast receiver 22 via the antenna 21,
Alternatively, the modulator 23 disturbs the synchronizing signal of the video signal from the video signal 12' and the studio 12'' by the signal from the scrambler 24, and the modulator 23 converts the audio signal into AM using a signal that reproduces the disturbed synchronizing signal. modulate, mixer 1
Mix with other channels' signals at 0A, and then connect to amplifier 1.
6 and distributed to each home by a distributor 17, so that the audio and video can be reproduced on a television receiver 19 via a set top terminal 18 only to subscribers of that channel.

Next, regarding the structure of the set-top terminal 18,
This will be explained using FIG.

The tuner 25 uses the signal from the distributor 17 to monopolize only the signal of the channel received by the remote control receiver 26 or the keypad 27, and the descrambler 28 descrambles the synchronization signal with the distorted video signal and displays it correctly. and sent to the television receiver 19, where the audio and video are played back.

At this time, whether or not to descramble the disturbed synchronization signal and reproduce it correctly is determined by the fact that the memory 29 stores whether or not the channel is subscribed to.

In other words, if the channel is subscribed to, the address receiver 30. Decoder 31, CPU
32 to the memory 29, and if this information has been input, the tuner 25 selects the channel via the PLL 33 based on the instruction, and the CPU 32 sends the video to the descrambler 28. A command is issued to descramble the disturbed synchronization signal and reproduce it correctly. Note that 34 is a power supply circuit.

Also, to explain the scrambling and descrambling of the synchronization signal, in FIG. As a result, the synchronization signal becomes distorted.

When the signal is descrambled, the signal protrudes downward again as a synchronization signal as shown in (c), and is correctly reproduced as a synchronization signal, resulting in a synchronized video. Note that L in (c) is the output of the AM detection circuit 40,
M is the output from the pulse generation circuit 41.

Next, the descrambler 28 will be explained with reference to FIG.

The scrambled television signal tuned by the tuner 25 is divided into two at the entrance of the descrambler 28, and one is sent to the RF amplifier 35 whose amplitude can be increased by a pulse input from the outside.

The other signal is band-limited by a bandpass filter 36 and sent to an amplifier 37, amplified by the amplifier 37, and video detected by a video detection circuit 38. Next, only the 4.5 MHz beat is extracted from the output signal of the video detection circuit 38 by a band pass filter 39, and the A
Perform M detection.

The AM detection output is further divided into two parts, one of which is input to the pulse generation circuit 41. The other side is the peak detection circuit 42
Here, the peak voltage of the output waveform of the AM detection circuit 40 is detected, and the half value of the peak voltage is outputted by the half value detection circuit 43 and inputted to the pulse generation circuit 41. The pulse generating circuit 41 compares the AMM wave output with the half value of the peak voltage of the AMM wave output, and generates a pulse when the voltage of the AMM wave output is high. The pulse width from the rise time of this pulse is adjusted by the pulse width adjuster 42a to be the same width as the compressed period of the synchronization signal, and the RF amplifier 35
sent to. Since the RF amplifier 35 increases the amplitude only during the period when the pulse is input, the scrambled synchronization signal can be descrambled.

FIG. 4(a) shows the case of standard AM modulation degree.

Since the threshold voltage 44 is determined by the half-value detection circuit 43 to be half of the output of the peak detection circuit 42, the AM
A rectangular pulse is generated at 50% of the output 45 of the M-wave generator 40.

FIG. 4(b) shows a case where the modulation degree is larger than the standard, and as the peak voltage 45a rises, the threshold voltage 44a, which is half of the peak voltage 45a, also rises, and a rectangular pulse is generated with an AM detection direction of 50%. Therefore, the rise retiming of the rectangular pulse is the same as in the case of the standard modulation degree shown in FIG. 4(a).

FIG. 4(c) shows a case where the modulation degree is smaller than the standard. When the peak voltage 45b falls, the threshold voltage 44b also falls, so in this case as well, the rise timing of the rectangular pulse is the same as the standard shown in FIG. 4(a). The same is true for the modulation depth. Therefore, the rise timing of the rectangular pulse is constant regardless of the degree of modulation.

FIG. 5A shows a graph of the rise timing deviation 16 of the conventional example and the rise timing deviation 17 of the embodiment of the present invention. The present invention shows that even if the AM modulation degree changes, the rise timing of the rectangular pulse does not change.

FIG. 6 shows a peak detection circuit 42, etc., which is composed of a diode D, a capacitor C connected in parallel to the diode D, and a resistor R1 connected in parallel. Further, the half-value detection circuit 43 is constituted by resistors R2 and R3 connected in parallel to the parallel connection of the capacitor C and the resistor R1, and the midpoint of the resistors is connected to the pulse generating circuit 41. Furthermore, the AMM wave circuit 40 has a limiter amplifier 4.
0a and a multiplier 40b.

Next, 46 is a current mirror circuit for creating a reference voltage for the mute circuit 47 which cuts the pulse output when the above-mentioned one channel is selected, for example, which is not scrambled. Further, 48 is a constant voltage circuit for stabilizing the lower potential of the resistor R3, and this can be replaced with ground.

(Effects of the Invention) According to the present invention, pulses are always generated using 50% of the detector output as a threshold, so even if the level or degree of modulation of the modulation signal changes, pulses are always generated at a constant timing. A circuit receiving this pulse can operate stably. Since the 50% point can always be used as the threshold, low,
This has the effect of minimizing the influence of noise in the high voltage section and allowing operation with stable timing.

[Brief explanation of drawings]

Fig. 1 is a circuit diagram showing a descrambling unit according to an embodiment of the present invention, Fig. 2 is a configuration diagram showing an example in which an embodiment of the present invention is applied to a cable television, and Fig. 3 is a set-top terminal section of the same. 4 is a waveform diagram of the same, FIG. 5 (A) is a characteristic diagram showing the characteristics of the invention-embodiment product and the conventional product, and FIG. 5 (B) is the scramble and descramble of the video signal. 6 is a circuit diagram showing the same pulse generating circuit, FIG. 7 is a block diagram of the conventional example, and FIG. 8 is a waveform diagram of the same. 28... Descrambler, 40... AM detection circuit, 41... Pulse generation circuit, 42... Peak detection circuit, 43... Half value detection circuit. Patent applicant Matsushita Electric Industrial Co., Ltd. Figure 3, former Figure 4 Figure 5 (A) - AM I copper layer Figure 7

Claims (18)

[Claims] (1) A peak detection circuit that detects a constant peak voltage from a periodic input signal, a half-value detection circuit that detects the half value of the peak voltage, and a point where the half value and the input signal are compared and matched. 1. A pulse generating device comprising: a pulse generating circuit having a pulse rising point at . (2) The pulse generator according to claim (1), characterized in that the output of the AM detection circuit is divided into two and one is supplied to the pulse generation circuit and the other to the half value detection circuit. . (3) The pulse generator according to claim (2), wherein the output of the pulse generator circuit is configured to be used as a descramble signal of a scrambled signal. (4) The pulse generator according to claim (3), wherein the output of the pulse generator circuit is used as a descramble signal for a signal scrambled via a pulse width adjuster. (5) The pulse generator according to claim (2), wherein the output of the pulse generator circuit is used as a descramble signal for a scrambled synchronization signal of a video signal. (6) The pulse generator according to claim (5), wherein the output of the pulse generator circuit is used as a descramble signal for a scrambled signal via a pulse width adjuster. . (7) A peak detection circuit that detects a constant peak voltage from a periodic input signal, a half-value detection circuit that detects the half value of the peak voltage, and a comparison between the half value and the input signal to determine whether they match. 1. A pulse generation device comprising: a pulse generation circuit that uses a point as a rising point of a pulse, and the peak detection circuit is constituted by a parallel connection of a resistor and a capacitor. (8) The pulse generator according to claim (7), characterized in that the output of the AM detection circuit is divided into two and one is supplied to the pulse generation circuit and the other to the half value detection circuit. . (9) The pulse generator according to claim (8), wherein the output of the pulse generator circuit is configured to be used as a reproduction signal of a scrambled signal. (10) The pulse generator according to claim (9), wherein the output of the pulse generator circuit is used as a descramble signal for a signal scrambled via a pulse width adjuster. (11) Claim (8) characterized in that the output of the pulse generation circuit is configured to be used as a descramble signal of a scrambled synchronization signal of a video signal.
The pulse generator described in Section 1. (12) The pulse generator according to claim (11), wherein the output of the pulse generator circuit is used as a descramble signal for a scrambled signal via a pulse width adjuster. . (13) A peak detection circuit that detects a constant peak voltage from a periodic input signal, a half-value detection circuit that detects the half value of the peak voltage, and a comparison between the half value and the input signal to determine whether they match. a pulse generation circuit that uses a point as a rising point of a pulse, the peak detection circuit is constituted by a parallel connection of a resistor and a capacitor, and the half value detection circuit is constituted by a resistor connected in parallel to the parallel connection. A pulse generator in which the midpoint of the resistance of this resistor is connected to a pulse generator circuit. (14) The pulse generator according to claim (13), characterized in that the output of the AM detection circuit is divided into two and one is supplied to the pulse generation circuit and the other to the half value detection circuit. . (15) The pulse generating device according to claim (14), wherein the output of the pulse generating circuit is used as a descramble signal of a scrambled signal. (16) The pulse generating device according to claim (15), wherein the output of the pulse generating circuit is configured to use a signal scrambled via a pulse width adjuster as a descrambled signal. (17) The output of the pulse generation circuit is configured to be used as a descramble signal for a scrambled synchronization signal of a video signal.
) The pulse generator described in item 2. (18) The pulse generator according to claim (17), wherein the output of the pulse generator circuit is used as a descramble signal for a scrambled signal via a pulse width adjuster. .